Creation and Identification of Unforgeable Printable Image Information Data

ABSTRACT

The present application relates to a method for producing and authenticating unforgeable printable image comprising information color values and inference color values. The present application further provides for unforgeable printed images.

The present invention relates to a method for producing unforgeable printable image information data that can be printed with conventional printers or printing processes, and which are easily decodable or recognizable by means of a camera unit such as a Smartphone, for example.

According to statements by the World Customs Organization (Brussels), the economic impact of counterfeit products placed on the market increases from year-to-year in the global economy. For this reason, and since Smartphones for example are widespread, relatively inexpensive and are well suited for the authentication of codes applied on a package, suitable processes are increasingly developed and used for this purpose.

AlpVision offers a “Varnish Cryptoglyph®” product on the market for example, which introduces micro-holes as a pseudo-random pattern into a varnish coating that are invisible to the human eye. In this context, the invisible micro holes are introduced into cartons, blister packs and labels during a printing process. A corresponding authentication is performed by a software application on the Apple iPhone 4 Smartphone. However, the microholes can be introduced only with relatively great difficulty, which requires a special varnish for this purpose.

Special labels for example such as hologram labels, Guilloche pattern labels, which change the image depending on the viewing angle or become visible only with special screen filters, are expensive to produce and are difficult to handle for the end user. Moreover, forgers meanwhile also increasingly copy standard holograms. Here too, Smartphone based solutions are available for this from InkSure and Jura JSP GmbH, for example.

US 20120243797 A1 discloses a method for applying an image with imperfections onto a package, of which a photograph can be taken with a Smartphone for instantaneous identification. For this purpose the imperfections are so small that they are imperceptible to the human eye. Black-and-white or color imperfections with relatively high contrasts can be photographed easily and can also be correspondingly printed again easily with a printer.

Treméau et. al. publish various methods for watermarking in the paper “Recent Trends in Color Image Watermarking” in the “Journal of Imaging Science and Technology, 2009, Vol. 53(1), 10201 pages 1-15.” For this purpose, it is proposed to use the colors of an image in quantized stages and according to a specified distribution. It is also recommended to use colors with a small color difference for example, although it is difficult to define the quality of recognizing the small color differences. In this context, half-tone coloring is also mentioned.

A method for watermarks or for hiding a message in an image without being able to identify the message with the eye, was published by Thomas et al. in the paper “Image Watermarking based on color quantization process” in the publication “Electronic Imaging 2007, Int. Society for Optics and Photonics, 2007, page 650603.”

In the paper “Watermarking and authentication of color images based on segmentation of the xyY color space” in the Journal “Imaging Science and Technology, 2006, Vol. 50(5): 411-423” Chareyon et al. published a method for hiding a watermark by changing the color in certain areas according to a pattern.

In the paper “Pre-separation clustered-dot color halftone watermarks: Separation estimation based on spatial frequency content” in the “ Journal of Electronic Imaging, 2010, Vol. 19(4), 43007, page 1-12,” Oztan et al. publish a method for capturing CMYK expressions using a RGB scanner.

In the paper “User-friendly random-grid based visual secret sharing” in the publication “IEEE, Trans. on Circuits and Systems for Video Techn., Vol. 21(11), 2011, 1693-1703,” Chen et al. publish a method for hiding one or two secret images or logos in an image.

In the paper “Digital Image Ownership Verification based on spatial Correlation of Colors” in the publication “Image Processing (IPR 2012), IET Conference on IET, 2012, page 1-5,” Surekha et al. publish a method for splitting a watermark into two partial images wherein a first partial image is introduced during printing and a second partial image is used during the recognition of the first partial image, in order to identify the watermark.

In the paper “Revenge of physical—mobile color barcode solutions to security challenges” in the publication “Proc. Optical Document Security, 2010, S.184-197” Simske et al. publish a method for the selection of colors for bar codes.

Likewise, methods for the introduction and recognition of watermarks hidden for the eye are presented in the documents WO2004028140 A1, US20080247002 A1 and U.S. Pat. No. 5,315,098 A.

In addition, solutions exist which offer very large copy protection but require special equipment and varnishes, where the corresponding printing methods are very expensive and are therefore unsuitable for many applications. Numerous copy protection features are frequently introduced on banknotes for identification for example, which make it impossible in particular for end-users to identify all of them. Using smart phones, such features can be stored as patterns and be compared with the respective pattern, however.

SUMMARY OF THE INVENTION

An object of the present invention is therefore to eliminate the disadvantages from the prior art by providing a method for producing preferably unforgeable image information data, which can be printed onto paper, carton or suchlike with a standard printing method and which are perceptible to the naked, human eye and that are well identifiable with a camera unit nevertheless, such as a camera-based Smartphone.

The above problems and further problems to be derived from the specification are solved by a method for producing unforgeable printable image information data or by a method for recognizing the image information data according to the features of the independent claim 1 or 18. Further advantageous embodiments of the present invention are stated in the dependent claims.

The advantages accomplished with the present invention in particular consist in that the unforgeable image information data can be applied on paper or carton or suchlike using conventional printing methods or printing devices. The production or the printing of the unforgeable image information data on papers, carton or packaging requires almost no adaptation period, contrary to other methods according to the prior art. The unforgeable image information data can also preferably be very well integrated in a previously specified design or be applied onto existing packaging or labels.

In particular, because information image dots or information pixels in the image information data are preferably printed in the first screen areas encoded preferably only by slightly different color values, these color values or information pixels can no longer be recognized or be distinguished from one another with the naked eye. In this context, the color values or the information color values for encoding are so weakly contrasted that they can almost or at least not be securely distinguished, even under a microscope.

Another aggravating factor for an attempted forgery is that in addition to the information pixels in the image information data, also interference pixels are still arranged in the adjacent interference fields. As a result, a visual perception by a microscope or a camera or scanner-based detection of the information pixels is complicated further. For this purpose, the interference color values assigned to the interference pixels and information color values of the information pixels are defined and printed so that they are only slightly different or contrasted, so that they can be differentiated or distinguished only with great difficulty. A forgery is particularly also significantly complicated in that the difference in color value in adjacent interference pixels compared to the information pixels is so small that it can just be recognized and distinguished by the camera unit with a specific software. Every printing unit moreover produces an equipment specific print as a black-and-white or color print that is slightly different from other printing units.

By initially producing the image information data which are then printed by a printing unit and can be measured subsequently, it is even possible to evaluate the equipment specific printed color values of the image information data for subsequent authentication or decoding. It is therefore also possible to use one or several equipment specific print values of specific approved printing units virtually as fingerprints for the authentication or decoding. In this context, the measured color values or a relative contrast distribution of the printed color values are transmitted to the camera unit or Smartphone for evaluation or authentication via the Internet. For this purpose, the contrasts or color values of the information color values and interference color values are preferably few and just different enough so that they can be reliably distinguished for authentication by the camera units or Smartphones. This makes the authentication even more unforgeable.

During the recognition of the image information data by the camera unit or Smartphone, an Internet connection is not absolutely necessary if the required decoding data for authentication of the respective image information data have been downloaded previously. As a result, authentication is possible in real time, in that the camera unit or Smartphone performs and displays the authentication instantaneously.

A further advantage of the present invention consists in that it can also be used easily and cost-effectively by end-users. Similarly, it can be used in a few bar/QR code applications on Smartphones and the operation requires no special knowledge. The installation and updating of recognition software on the camera units or Smartphones is done by the Apple App Store or Google Play store, or suchlike.

By simple and easily permutable encoding or error encoding and by the simple transmission of the decoding data necessary for the authentication to the camera unit or Smartphone, the creation of unforgeable image information data can be changed very easily at specific time intervals.

A preferred embodiment according to the present invention is illustrated in the subsequent drawings and in a detailed description, but is not intended to limit the present invention thereto.

The drawings show:

FIG. 1 shows an image area with a first screen with corresponding first screen areas and a logo area positioned therein;

FIG. 2 shows the image area, where the first screen areas are respectively filled with one information image dot;

FIG. 3 shows an upper half of the image area of FIG. 2 with the first screen, where the first screen areas are respectively filled with the respective information image dot and additionally with interference pixels;

FIG. 4 is a schematic representation of a part of the image area with the first screen, which is marked with thick lines and is subdivided by a checkered second screen;

FIG. 5 is a schematic representation of a part of the image area with the first screen and the second screen, wherein the second screen is filled with respective color values; and

FIG. 6 is a diagram with a scale of color values in which information color values and interference color values are plotted.

DETAILED DESCRIPTION OF AN EMBODIMENT

The objective of the method according to the present invention is to initially produce unforgeable, printable image information data from specific information data and subsequently recognize and authenticate the corresponding image information data printed on paper, carton or packaging.

For this purpose, the specific information data are put into a form of binary information image dots, which happens in that the information data are transferred into the binary information image dots by a specific encoding rule. In this context, the produced binary information image dots are arranged grid-like in a first screen and respective first screen areas

R1 within an image area. In this context, the first screen can be a unidimensional or two-dimensional screen, such as a standard barcode or a matrix barcode, for example. Three-dimensional screens are also conceivable, although this would require customized printers for printing.

According to the present invention, the first screen or the first screen areas R1 therein is subdivided by a second screen, so that the plurality of second screen areas R2 is arranged in the respective first screen area R1. In this context, a plurality is at least two or more. Preferably, the subdivision in the second screen areas is done in the form of a checkerboard, bar-shaped or like a cake segment, wherein other forms of partitioning are also possible.

Using an information field assignment rule, one of the second screen areas R2 in the respective first screen area R1 is defined as an information field lxy for the respective information image dot, wherein at the same time the remaining second screen areas R2 of the respective first screen area R1 are defined as interference fields Sxy.

According to the binary value 1 or 0 of the information image dot, a first information color value IF1 is assigned to the respective information field lxy at a value 1 and a second information color value IF0 at a value 0. The color value assignment is performed according to an information color value assignment rule. In this context, the second information color value IF0 differs from the first information color value IF1.

According to an interference color value assignment rule, specific interference color values are assigned to the respective interference fields Sxy. This is intended to encumber subsequent recognition and differentiation of the information fields lxy from the interference fields Sxy and accordingly a recognition of the first IF1 and the second information color value IF0.

The color values of the second screen areas with the respective first IF1 and second information color values IF0 and the interference color values will be ultimately stored as the image information data and preferably provided for printing onto the paper, carton or packaging.

FIG. 1 shows an example of the image area R0, which is subdivided by the first screen with the corresponding first screen areas R1. Preferably, in addition a logo area R3 can also be arranged in the image area R0. The logo area R3 is preferably arranged in the image area such that the logo area R3 is surrounded partially or completely by the first screen areas R1. Preferably, the first screen areas R1 are separate from the logo area R3, so that they do not overlap. For this purpose, the first screen areas R1 can surround the logo area R3 partially or completely, for example. It is also possible however that a logo and/or other graphic characters are represented by the interference fields Sxy.

The first screen areas R1 are subdivided by the second screen. In the present example, four second screen areas R2 arranged in the form of a checkerboard are produced for each first screen area R1. In FIG. 1-3, the area subdivisions of the second screen areas R2 are not represented by lines, as they are for example represented in FIG. 4 and FIG. 5, however. In the present example, in each case the upper left screen area R2 of the respective first screen area R1 is defined as the information field lxy, and the remaining three screen areas R2 are defined as the interference fields Sxy.

FIG. 2 shows the image area R0, where the respective information image dots are respectively arranged in the information fields lxy, and where the information image dots are represented either by a lighter or comparatively by a somewhat darker blackening. In this way, the information image dots are distributed in the form of a matrix.

FIG. 3 shows the upper half of the image area R0 from FIG. 2, but with interference image dots that are additionally arranged in the respective interference fields Sxy. In that context, the interference image dots are preferably produced with a color value that differs only slightly from the color values of the information image dots. The color values of the interference image dots can preferably also be highly contrasted relative to the information image dots however, in order to cover or dominate the information image dots in terms of color. In this manner, the interference image dots can thus be produced colored and be arranged around the information image dots such as to produce preferably much interference and thereby make the information image dots more unrecognizable.

FIG. 4 shows a schematic representation of a preferred configuration of the first screen areas R1, which are subdivided marked by bold lines, and the second screen areas R2, which are separated marked by thin lines. In that context, the second screen areas R2 of a first screen area R1 are respectively partitioned into the one information field I1, I2-I8 as lxy and in the remaining interference fields S1 a-S1 c-S8 a-S8 cas Sxy. For that porpose, the information fields lxy and the interference fields Sxy are identified in the form of a matrix across a X-coordinate and a Y-coordinate. Other configurations or partitions, such as in the form of a cake segment, for example, are also conceivable in principle.

FIG. 5 shows the information fields lxy and the interference fields Sxy as an example, which are respectively filled with a corresponding color value. For this purpose, a first information color value IF1 is assigned to the respective information fields lxy depending on the value of the information image dot at a value of 1, and a second information color value IF0 is assigned at a value 0, wherein the assignment takes place according to an information color value assignment rule. According to an interference color value assignment rule, respective interference color values are assigned to the interference fields Sxy. In the present example, either a first interference color value SF1 or a second interference color value SF2 are assigned to the respective interference field Sxy. In that context, the first interference color value SF1 or the second interference color value SF2 are preferably assigned such that the sum is the same across all color values of a first screen area R1. In other words, in an information field lxy with a small color value IF0, three color values the sum of which is large are defined as interference color values, and in an information field lxy with a large color value IF1, three color values the sum of which is smaller are defined as interference color values compared with the large color value.

Here, a color value is defined for a color to be printed which includes a specific color or color composition and a specific color density. The colors or color values which are tantamount in this document are mostly produced as color screens onto which dots are applied. For this purpose, the color screen is produced from a composition of primary colors, which are respectively applied or printed with more or less density. For example, the color values are composed of printing inks like red, green, blue, yellow and black, for example. A lighter color is produced by less dense spectral loci, whereas a darker color is produced by denser printing of the spectral loci. In the following, the terms color value or color are to be regarded as being synonymous, wherein the color value is preferably produced by the color screen. It is also conceivable that the different color values are produced by different liquid colorants, however. More preferably, the respective color value is produced as dot matrix or as dot distribution with a specific dot density, however.

Preferably, all color values, such as the first IF1 and the second information color value IF0 and the interference color values can be printed with a conventional printing unit. For this purpose the printers are designed to produce the respective color value from its printing inks, such as for example for a print run or half-tone printing or also for black-and-white print or color laser print or for ink-jet printing.

The first information color value IF1, the second information color value IF0 and size of the information field lxy are preferably defined such that the respective information image dot is no longer perceptible to the naked eye. In that context, the first IF1 and the second information color value IF0 are preferably defined such that the information field lxy is filled with a color less than 25%. For that purpose, the preferred color is yellow for example, which is particularly difficult to detect with the human eye. Preferably, a size of 0.01-0.1 mm² or a diameter size of 0.11-0.36 mm is defined for the second screen area R2 and in particular for the information field lxy. Consequently, the first screen area R1 is preferably four times the size of the second screen area R2. The information image dots are therefore not simply small, but are also widely distributed and can be recognized with the eye only under a microscope. For this purpose, the color differentiation between the first information color value IF1 and the second information color value IF0 is preferably defined sufficiently small so that this cannot be differentiated with the human eye under a microscope.

Because of the information field assignment rule, preferably the respective information field lxy will always be arranged at the same location in the respective first screen area R1, or in other words always in the same second screen area R2 of the respective first screen area R1. However, according to the information field assignment rule, the information field lxy can also be arranged in alternating second screen areas R2 of adjacent first screen areas R1.

The respective interference color value for the respective interference field Sxy are [sic] preferably defined by the interference color assignment rule such that a specific mean color value in the respective first screen area R1 is produced as an average across the information field lxy and the remaining interference fields Sxy.

The defined mean color values of the first screen areas R1 are preferably produced such that for this purpose either a first for a second defined mean color value is produced. In this context, the defined mean color values are preferably defined such that the defined mean color values are adjacently arranged checkered across adjacent first screen areas R1. To this end, producing a plurality of defined mean color values is also conceivable. In this manner, the adjacent first screen areas R1 can be better distinguished from each other.

The mean color values defined from the first screen areas R1 are preferably defined such that a second encoded information is transmitted by means of them. The second information may be a readable information, for example. The second information may be a print date and/or statement regarding a print batch or a printing unit, for example. Preferably the second information can also be arranged outside of the image area R0 or as part of the logo area R3, however.

Preferably, the defined mean color values of the first screen areas R1 are defined as at least one first or one second defined mean color value such that the defined first mean color value corresponds to the first information color value IF1 and the second defined mean color value corresponds to the second information color value IF0

The respective interference pixel color value is preferably defined such that it has less than 25% contrast difference to the first information color value IF1. In this context, the contrast difference is more preferably below 5%.

Preferably, the plurality of the second screen areas R2 per the first screen area R1 is greater than or equal three to form at least two interference fields Sxy next to the one information field lxy. For that purpose, in the event that the first information color value IF1 is assigned to the information field lxy, a first interference pixel color value SF1 is preferably assigned to a first interference field, said first interference pixel color value SF1 being higher than the first information color value IF1, and a second interference color value SF2 is assigned to a second interference field, said second interference color value SF2 being lower than the first information color value IF1.

Preferably, the first interference pixel color value SF1 is defined at a value that exceeds the first information color value IF1 only to such an extent as to barely permit reliable recognition by the camera unit. Preferably in that context the second interference color value SF2 is defined at a value that falls below the first information color value IF1 only to such an extent as to barely permit reliable recognition by the camera unit.

For that purpose, also a variety of four or nine second screen areas R2 to a first screen area R1 is preferred. Other subdivision varieties are also possible.

Preferably, using the interference color value assignment rule, the second or a further information is transmitted by the corresponding image information data by means of the interference fields.

For this purpose, the second information is also used for encrypted encoding of the information data in the form of the binary information image dots. As a result, the encoding rule can be changed permutationally, for example.

Preferably, a logo, one or multiple graphic characters and/or an image are depicted by the second information. By means of the second information, the print batch, the printing unit and/or the print date can be transmitted. Alternatively, the second information can also be printed on the edge of the image area R0 or in the logo area R3.

For this purpose, the second information includes measured color values originating from a print by the printing unit and that were measured from it. In this manner, printing unit specific color values can be measured and be transmitted to the camera unit or Smartphone for authentication or decoding.

Preferably, the interference color value assignment rule is designed to depict or to transmit the second information by means of the respective interference fields Sxy. In this context, the second information is preferably defined by a function depending on the information data. Preferably, this function can be an algorithm, a function for establishing a checksum, a sign change, a quadrature, or another function from the information data.

Preferably, the encoding of the information data can be performed into the form of the binary information image dots, for example as binary unidimensional or two-dimensional barcode, as alphabetic character text or numerical text.

Preferably, the information data can include a serial number and/or product data.

Preferably, the serial number and/or the product data can also be encoded in the second information.

The image information data can be printed onto all printable materials, such as paper, carton, packaging and suchlike, for example.

Decoding—Authentication

Even automatic recognition and differentiation can be performed only with great uncertainties, in that the first information color value IF1 and the second information color value IF0 are defined as a small difference in color or contrast. For this purpose, preferably the first IF1 and the second information color value IF0 are defined as percentile color values of a defined interference color value with sufficiently high color density, in order to be able to measure the defined interference color value securely. For example, in this context, then the first information color value IF1 is defined as 20% of the defined interference color value and the second information color value IF0 is defined as 17% of the defined interference color value, for example. Authentication can be securely performed by knowing these percentages.

The method according to the present invention for recognizing and decoding of the printed image information data in image area R0, which were printed onto paper, carton, packaging boxes, adhesive labels or suchlike as described above, essentially involves the following steps. For this purpose, preferably the recognition and decoding will be performed by a microcontroller supported camera unit, a camera, or a scanner in conjunction with a PC, a Smartphone or suchlike, which will be named camera unit hereafter.

Initially, the camera unit is preferably aligned by using at least one easily visible and recognizable mark located in or on the printed image area. A specific logo with a high-contrast colored bordering can function as a mark, for example. After the camera unit is aligned, an image is recorded with the image area R0 and is stored. Preferably, for the alignment of the camera unit also recognition algorithms are used, which detect and indicate in real time whether and how the camera unit is and/or should be aligned. Preferably, during the automatic detection and a sufficient satisfactory alignment, the image will be triggered and captured automatically. For this purpose, the image includes the image area R0 and the printed image information data located therein.

By using a pattern recognition algorithm on the image, said pattern algorithm being designed to recognize the first screen with the first screen areas R1 and the second screen with the second screen areas R2. Preferably, for this purpose the image will be correctly aligned, rotated, rectified and cropped according to the image area R0, beforehand. Preferably, the pattern recognition algorithm includes a comparison algorithm with a specific pattern. For the recognition of the first R1 and second R2 screen areas, preferably a histogram analysis is performed, which displays the rows and columns.

By using the information field assignment rule, the information fields lxy and the interference fields Sxy are defined from the detected second screen areas R2.

The color values of the respective information fields lxy are subsequently defined by means of their color values, using a further histogram analysis. Preferably, during the histogram analysis two color values with respectively significant accumulation are determined and defined as the first information color value IF1 and the second information color value IF0.

In this context, the histogram analysis for the recognition and differentiation of the color values is preferably designed such that after the first information color value IF1 is approximately recognized, the existing color values with a higher resolution in the area of the first information color value IF1 are analyzed and distinguished. For this purpose, the first IF1 and the second information color value IF0 and the interference color values are then distinguished from one another. In particular, in this manner preferably the first information color value IF1 is distinguished from the two adjacent interference color values SF1 and SF2, as a result of which the first information color value IF1 and the two adjacent interference color values SF1 and SF2 are distinguished as measured color values and can therefore be recognized again.

According to the information color value assignment rule, the value 1 is assigned to the information fields lxy with the first information color value IF1, and the value 0 is assigned to the information fields lxy with the second information color value IF0. As a result, binary information image dots are produced in the information fields lxy.

Thereafter, a decoding rule, which corresponds to the encoding rule is employed on the binary information image dots and the information data printed or recovered therefrom. If the recovered information data correspond with the information data, which were either stored or can be accessed via the Internet, then the authenticity of the recovered information data can be displayed by the camera unit directly or indirectly. Otherwise a forgery can be displayed. Preferably, above a specific degree of correlation, it is assumed that the recovered information data conform with the information data so that individual deviating pixels will not produce a false-negative result.

For this purpose, the pattern recognition algorithm is designed to initially recognize the first screen with its first screen areas R1 as a checkered pattern by low-pass filtering, whereupon edges of a low-pass filtered pattern are defined, and therefore the first screen and the first screen areas R1 can be defined.

Preferably, the mean color values of the first screen areas R1 are defined, wherein at least two significant distinguishable mean color values are recognizable by a further histogram analysis, wherein an evaluation of the mean color values will also be considered for an authentication of the printed information data.

Preferably, for authentication of the information data and, if available, a second information from the interference fields will be compared with a database, whether the information data and, if available, the second information are still admissible or not. Preferably, in this context the database is represented by a memory area or a memory value in the camera unit or by data that are accessible via the Internet, for example.

Preferably, the decoding and recognition algorithms are designed so that they can distinguish the first IF1 and the second information color value IF0 from one another securely, in that according to the information color value assignment rule known to the camera unit the corresponding binary values from both the larger color value and the smaller color value are assigned.

Preferably, the decoding and recognition algorithms are also designed such that they can distinguish the first SF1 and the second interference color value IF0 from one another securely by the histogram analysis, in that the corresponding values are distinguished and assigned according to the information color value assignment rule known to the camera unit.

Preferably, the recognition and decoding of the printed image information includes also the following process steps:

-   -   using the function, which is used for producing the unforgeable         printed image information data for producing the second         information depending on the information data, for the         information data, in order to obtain a calculated second         information therefrom;     -   defining a detected second information from the interference         fields Sxy according to the first assignment rule; and     -   comparing the calculated second information and the detected         second information, wherein during correlation the         authentication is performed, and during a deviation between the         calculated second information in the detected second         information, the authentication is rejected.

For clarity, it still be pointed out that by interference pixel, an interference field Sxy with an interference color value, and by information pixel, an information field lxy with an information color value, is to be understood.

Further possible embodiments are described in the following claims. In particular, the different features of the embodiments described above can also be combined with one another, unless they conflict in terms of technology.

The reference numbers cited in the claims serve for improved comprehensibility but they do not limit the claims to the forms illustrated in the figures.

LIST OF REFERENCE SYMBOLS

-   FW color value -   lxy information field -   Sxy interference field -   IF1 first information color value -   IF0 second information color value -   SF1 first interference color -   SF2 second interference color -   R0 image area -   R1 first screen area -   R2 second screen area -   R3 logo area -   X, Y coordinates 

1. A method for producing unforgeable printable image from information data, comprising following steps: encoding the information data in a form of binary information image dots by means of an encoding rule, wherein the binary information image dots are arranged screen-like according to a first screen in the respective first screen areas (R1) within an image area (R0); partitioning the respective first screen areas (R1) by a second screen to respective second screen areas (R2), so that a plurality of second screen areas (R2) is formed for each first screen area (R1); determining a respective information field (lxy) from the respective second screen areas (R2) of the respective first screen area (R1) according to a first assignment rule and determining the remaining second screen areas (R2) as interference fields (Sxy); assigning to the respective information field (lxy) depending on the value of the information image dot at a value of 1 a first information color value (IF1) and at a value 0 a second information color value (IF0) according to an information color value assignment rule; determining and assigning a respective interference color value to the respective interference fields (Sxy) according to an interference color value assignment rule; and storing the second screen areas with the respective information color values (IF1, IF0) and interference color values as the image information data; and printing the unforgeable printable image based on the image information data.
 2. The method according to claim 1, wherein the first information color value (IF1), the second information color value (IF0) and a size of the respective second screen area (R2) of the information field (lxy) are determined such that the respective information image dot is imperceptible to the naked eye.
 3. The method according to claim 2, wherein the first (IF1) and the second information color value (IF0) fills the second screen area (R2) less than 25%, the second screen area (R2) has the size of 0.01-0.1 mm² or a diameter of 0.11-0.36 mm, and a surface area of the first screen area (R1) is larger than four times the surface area of the second screen area (R2).
 4. The method according to one of the preceding Claims, wherein in step c) by means of the first assignment rule the respective information field (lxy) in the respective first screen area (R1) is either always arranged in the same second screen area (R2) of the respective first screen area (R1) or in alternating second screen areas (R2) of adjacent first screen areas (R1).
 5. The method according to one of the preceding Claims, wherein in step e) by means of the interference color value assignment rule the respective interference color value for the respective interference field (Sxy) is determined such that in this context a specific mean color value of the first screen area (R1) is produced as an average across the information field (lxy) and the remaining interference fields (Sxy).
 6. The method according to claim 5, wherein the determined mean color values of the first screen areas (R1) are defined as at least a first or a second defined mean color value; and/or wherein the determined mean color values of the first screen areas (R1) are defined as at least a first or a second defined mean color value and the defined mean color values are arranged checkered adjacently across adjacent first screen areas (R1).
 7. The method according to claim 5, wherein the determined mean color values of the first screen areas (R1) are determined as at least a first or a second defined mean color value such that the defined mean color values are arranged checkered adjacently and the first and the second determined mean color value is determined such that an additional second information is encoded therein and transmitted.
 8. The method according to claim 5, wherein the mean defined color values of the first screen areas (R1) are determined as at least a first or a second defined mean color value such that the defined first mean color value corresponds to the first information color value (IF1) and the defined second mean color value corresponds to the second information color value (IF0).
 9. The method according to claim 1, wherein the respective interference pixel color value is defined such that it has a lower than 25% contrast difference to the first information color value (IF1) and in this context preferably has a lower than 5% contrast difference.
 10. The method according to claim 1, wherein the plurality of the second screen areas (R2) per first screen area (R1) is greater or equal three, in order to establish at least two interference fields (Sxy) in the respective first screen area (R1) next to the one information field (lxy), wherein in case that the first information color value (IF1) is assigned to the information field (lxy), a first interference pixel color value (SF1) is assigned to a first interference field, said interference pixel color value (SF1) being higher than the first information color value (IF1), and a second interference color value (SF2) is assigned to a second interference field, said second interference color value (SF2) being smaller than the first information color value (IF1).
 11. The method according to claim 10, wherein the first interference pixel color value (SF1) is determined at a value that exceeds the first information color value (IF1) only to such an extent as to barely permit reliable recognition by the camera unit; and/or wherein the second interference color value (SF2) is determined at a value that falls below the first information color value (IF1) only to such an extent as to barely permit reliable recognition by the camera unit.
 12. The method according to claim 1, wherein by means of predetermined arranged interference fields in the first screen, a second information is transmitted into the image information data by an assignment of corresponding interference color values as a result of the interference color value assignment rule.
 13. The method according to claim 8, wherein the second information in step a) is used for an encrypted encoding of the information data into the form of the binary information image dots.
 14. The method according to claim 8, wherein a logo or graphic character or an image is depicted by the second information; and/or wherein a print batch identification is transmitted by the second information.
 15. The method according to claim 1, wherein the interference color value assignment rule is designed to depict or to transmit a second information by means of the respective interference fields (Sxy).
 16. The method according to claim 7, comprising the method step: producing the second information as a function depending on the information data, wherein the function is a checksum, an inversion, a quadrature or another function of the information data.
 17. The method according to claim 1, wherein in addition an identification of a print date or of a print batch is applied in the image information data or on the border of the image information data, in order to transmit by means of the identification currently printed and measured color values for a corresponding decoding.
 18. The method for recognition and decoding of printed image information data in an image area (R0), with a microcontroller supported camera unit or a Smartphone, comprising the following steps: aligning the camera unit onto the image area (R0) and initiating and storing an image with the printed image information data; applying a pattern recognition algorithm on the image, said pattern algorithm being designed to recognize the image area (R0), a first screen with first screen areas (R1) and a second screen with second screen areas (R2); determining information fields (lxy) and interference fields (Sxy) from the second screen areas (R2) of the respective first screen areas (R1) by means of a predetermined first assignment rule; determining of a first information color value (IF1) and a second information color value (IF0) in the respective information fields (lxy) by applying a histogram analysis across the color values of the information fields (lxy); assigning the respective binary values 1 or 0 to each of the first screen areas (R1) using the therein detected first (IF1) or second information color value (IF0) in the information fields (lxy) and an information color value assignment rule and thereby establishing binary information image dots; and applying a decoding rule on the binary information image dots and determining the printed information data there from.
 19. The method according to claim 18, wherein the pattern recognition algorithm is designed to initially recognize the first screen with its first screen areas (R1) as a checkered pattern as a result of a low-pass filtering, according to which borders of a low-pass filtered pattern are determined and therefore the first screen and the first screen areas (R1) can be determined; and/or wherein the histogram analysis for the recognition and differentiation of the color values particularly in the area of the first information color value (IF1) that is higher than the second information color value (IF0) is performed with higher resolution than in another color value area; and/or wherein the histogram analysis for the recognition and differentiation of the first information color value (IF1) and the second information color value (IF0) considers a predetermined minimum or maximum color value separation.
 20. The method according to claim 18, wherein mean color values of the first screen areas (R1) are defined and in this context at least two significant distinguishable mean color values are recognizable by a further histogram analysis, wherein an evaluation of the mean color values will also be considered for an authentication of the printed information data.
 21. The method according to claim 18, wherein for an authentication of the information data and, if available, a second information that is contained in the interference fields and is detected there from, are compared with a database, whether the information data and, if available, the second information are admissible or not.
 22. The method according to one of the foregoing claims 18, additionally comprising the following method steps: applying of a known function, which is used during production of the unforgeable printed image information data for producing a second information depending on the information data, on the information data and determining a calculated second information there from; determining a detected second information from the interference fields (Sxy) according to the first assignment rule; and comparing the calculated second information and the detected second information, wherein authentication takes place in the event of agreement and rejection in the event of deviation. 